CS276597B6 - Sinker radial position setting-up in circular knitter. - Google Patents

Abstract

Control device for adjusting the radial position of the sinkers in a circular knitting machine, constituted by a couple of cams for the radial drive of the sinkers, co-planar and concentrical with the axis of the cylinder and substantially circular, the innermost of which is stationary, and the outermost of which is radially approached and pushed away due to the effect of a countercam (17) externally placed around it, provided with approach and pushing-away lengths, which, by means of its discrete revolution, radially approaches it, and pushes it away.

Description

(57)

The device consists of a pair of locks (6, 7) for radial movement of the sinkers (3) concentric to the axis of the needle cylinder (39). The inner lock (6) is stationary and the outer lock (7) is radially zoomed in and spaced from the needle cylinder (39) by a lock ring (17) surrounding it and provided with depressions (18), while the outer lock has projections (16).

CS 276 597 B6

CS 276 597 B6

The invention relates to a device for adjusting and regulating the radial position of sinkers in a circular knitting machine, in particular in those machines which are equipped with devices for varying the density of the fabric to be produced by axial displacement of sinkers due to the reciprocating movement of needles.

In conventional circular knitting machines, the stitches are formed by the vertical reciprocating movement of the needles, which move in grooves formed along the forming lines of the needle cylinder, and by the movement of the movable sinkers mounted on the carrier fixed at the same end of the needle cylinder, It is known that for good machine operation and good goods quality, the sinkers must have some radial mobility to maintain tight knit loops so that the needle tongues can open and the resulting rows of stitches discard; the needle must not penetrate into the loops formed in the previous row during the formation of the next row. If this happened, the knit would have a mistake.

It is known that in the manufacture of tubular knitted articles, for example for the manufacture of hosiery, the length of the stitches produced in each row and thus the density of the knitted fabric must optionally be varied so that the desired sections of the tubular knitted fabric have different extensibility.

This is usually done by axially displacing the sinker carrier where the sinkers are driven by the lifting locks. An equivalent measure is the opposite axial movement of the sinkers forming the stitches and acting on the needles of the needles, since this measure is equivalent to shifting the entire needle path relative to the sinking plane of the sinkers, indicated by the letters A and B in FIGS.

In order for the eyelets to have the correct tension, the radially movable sinkers are arranged in most machines in the manner shown in Figures ΙΑ, IB. The sinkers 6 are mounted on a lower annular support 6 provided with radial grooves 2 in which the sinkers 6 are guided during their reciprocating movement in the radial direction. On the upper part of the sinker 4 are arranged two vertical nodes 8, 6, which alternately come into engagement with the inner lock 6 and the outer lock 6, which are supported by the lower annular carrier 6.

The contour of the two locks 8, 6 is shown in FIG. 2. The inner lock 6 forms essentially one body with the upper annular support 8 and is screwed to it by a screw 6. The outer lock 8 is divided into several sections, in the example shown in FIG. 2, into four sections, and is attached to the upper annular carrier 6 by pins 40 which are inserted into holes 11 of larger diameter than the pins 8. As a result, the outer lock 6 can move to some extent radially. The peripheral spring 12 exerts a slight thrust on the sections of the outer lock 6 and presses them slightly inwards. However, the radial direction force must never exceed the yarn tensile strength, so that when the needle 13 pulls the yarn 14 out and the yarn 14 exerts a pulling force outward on the sinker slot 15, the spring 12 must release and allow the sinker to retract.

The notch 15 and hence the entire sinker 8 is pushed inwardly by the spring 12 as far as the thread 4 permits. The thread 14 is therefore always taut and the loop is never released. Giant. IA corresponds to the situation in the formation of long loops where the sinkers jsou are in plane A, and Fig. IB corresponds to the short loops, where the sinkers leží lie in the lower plane B.

It will be appreciated that in forming the long stitches of FIG. 1A, the excess thread 14 allows the sinkers to move inwards along a long path. The planes A and B are normally called sinking planes.

According to FIG. 2, the inner lock 6 is active on both sides. Its inner contour 6i engages the butt 4 and pushes the sinker inwardly when the corresponding needles are lowered, and the outer contour 6e abuts the buttress 4 and pushes the sinker outwardly as the corresponding needles begin to sink after the thread 14 has been caught.

In periods when the inner lock 6 does not act on the butts 6, 7, the radial position of the sinker 6 is determined by the outer lock 7. The outer lock 6 only acts on the sinkers 6 by its inner circumference, which engages with the butt and pushes the sinkers 3 inwards, keeping the stitches of the yarn 14 constantly under tension. This technical solution is known, but has a number of drawbacks, especially when the machine is running at high speed.

In machines with high production, which operate at speeds above 1000 rpm, centrifugal forces act on the sinkers 3 and over them on the outer lock T so that this known solution cannot be used.

It should be appreciated that the circular knitting machine must be able to vary considerably the speed of rotation during the manufacture of an article, for example, when the needle distribution is changed.

When it is assumed that the machine will operate at high speed, a strong circumferential spring 12 is used which is able to counteract the effects of centrifugal forces occurring at high speeds. When the machine then operates at a lower speed, the centrifugal forces acting on the spring are small so that the spring force can exceed the tensile strength of the yarn 14 and the yarn 14 breaks.

In order to control the radial position of the sinkers in fast circular knitting machines, it is necessary to use a control system which determines the radial zooming and outward movement of the outer lock as a function of the length of the stitches produced. Several solutions have been proposed in the patent literature for this purpose. According to British Pat. No. 2 091 301, the stroke movement of the cams controlling the radial position of the sinkers is controlled by levers which move in vertical planes passing through the axis of the needle cylinder and are directly driven by the lifting movement of the sinkers.

According to German Pat. No. 3,246,653, the sections forming the outer lock T are pivoted on the upper annular support 13 and perform a pivoted approach and release motion controlled by the telescopic parts.

In another German Pat. No. 2,020,524, the length of the stitches is controlled by dividing the sinkers into half sinkers capable of radial relative movement relative to each other, thereby allowing the overall configuration of the sinker to be varied. The radial movement of the two half sinkers is controlled by acting on their knees, which are located at the ends of the sinker and one facing down and the other facing up. These nodes are located between sets of two locks located in different planes perpendicular to the axis of the needle cylinder. The locks are actuated by radially movable slides, which are pushed inward by radial springs and driven by further proximity locks located on the circumference.

Radial springs cause the position of the sinkers to be influenced by the speed of rotation of the machine. Moreover, all the solutions mentioned are extremely complex and do not ensure the accuracy and continuity of radial movement.

The object of the invention, which overcomes the prior art, is a device for adjusting the radial position of the sinkers in a circular knitting machine, provided with a stitch length adjusting device formed by a sinker carrier disposed in a plane perpendicular to the needle cylinder axis carrying concentric locks. the lock consists of radially movable sections. SUMMARY OF THE INVENTION The outer lock sections are provided with protrusions or depressions on the outer periphery and a rotatable lock ring, which has recesses or protrusions on the inner periphery, is disposed around the outer lock with radially displaced peripheral protrusions or depressions on the inner periphery. section of the outer lock by turning the lock ring.

The device according to the invention makes it possible to adjust the radial position of the outer lock in dependence on the height of the sinkers continuously and accurately.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 3A, 1B and 2 illustrate the state of the art as described above, FIG. 3 shows the inner lock, outer lock and lock ring of the invention; Fig. 3, Fig. 4 is a vertical sectional view of a circular knitting machine with the device according to the invention; Fig. 5A a plan view

And FIG. 5B is a side view of the pivoting mechanism of the invention.

Examples

As shown in FIG. 3, the outer lock 2, or more precisely its individual sections, is formed on the outer contour by a plurality of projections 16, which preferably have a rounded shape. Referring to FIG. 3, a rotary lock ring 12, the inner contour of which is provided with depressions 18 which are opposed to the projections 16 of the outer lock 11, are concentrically mounted around the outer lock 12 to determine the proximity of the outer lock 11 from the lock ring 12.

In Figures 3A, 3B, the projections 16 on the outer lock 7 and the depressions 18 on the lock ring 17 are shown in detail. However, it will be understood that this arrangement can be kinematic reversed and thus depressions 18 on the outer lock 7 and protrusions 16 on the lock ring 17.

When the machine is operating and the needle cylinder 39 is rotating, and together with the sinker-bearing system 2, the outer lock sections 2 abut against the lock ring 22 'by their projections 16 through the centrifugal force of the sinkers 3'. The adjustment of the radial position of the lock 10 ^is effected by rotating the lock ring 17 at an angle about its center C, which lies in the axis of the needle cylinder 22, ^{in the} direction of arrow R. In this rotation, each projection 16 arrives at a certain point of the depression. _ljB, so single! the outer lock section 2 ^is moved in or out.

In Figures 3A and 3B, the arrow A shows the position of the long eyelet, which corresponds to the longer ΐ movement of the sinkers 2 inwards, and the arrow B, the situation of forming short stitches, which corresponds to the longer movement of the sinkers 2 outwards.

I Rotate in the direction of arrow R from the minimum position to the maximum outside position

With the inward lock 2 and hence the movement of the sinkers 2, it is assigned by known means, e.g.

and; kinematic gearing 38 with bevel gears, to the minimum and maximum height of the sinker ejection plane, i.e. the plane 15.

Such a kinematic transmission 38 is shown in Figures 4, 5A and 5B.

Giant. 4 illustrates a circular knitting machine and a kinematic transmission 22 controlling the rotation of the cam ring 22. The sinker 2 which carries and guides the sinkers 2 is provided by the lifting and lowering mechanism 60

and. provided with a lifting plate 22, which is pivotable around the pin 20. The lifting of the carrier 2 causes the stitches resulting from the cooperation of the needles 13 and the sinkers 3 to be

And longer. Simultaneously with the raising and lowering of the needle cylinder 22 caused by the pivoting movement of the lifting plate 22, ^the bending of the lifting plate 19 in the axial direction is transmitted by a rod 22 which moves in the direction of arrow A 'to the arm 22.

1 'of the frame 23, while remaining parallel to its original position. This movement is limited by the passage pin 24, which moves together with the arm 22 in the through hole 1; 25 in the fixed frame 23.

, y | The movement of the arm 22 is transmitted by the adjustable push rod 26 to the arm 27, which is articulated on the axis 28 and performs a pivoting movement in the direction of the arrow B '. The conical toothed keg lo 29, keyed on the axle 28, rotates with it and causes the second conical

Wheel 30 in the direction of arrow C.

and?

and?. The second bevel gear 30 is keyed at the lower end of the axle 31, whose gaming end

The forked end 33 of this arm 32 surrounds the pin 34, thus fastening the rotation in the direction of the arrow R. The opening 35 in the second 33 and the cotter screw 36 allow blocking of the forked crosspiece of the arm 22 and the manes push rod. the arm of the name 32 on the axis 31.

Spring 37 locks

CS 276 597 B6

The device according to the invention makes it possible to adjust all the sections of the outer lock gradually and precisely by rotating a single control element and thus does not need a set of complex components whose function must be coordinated and controlled.

Claims (4)

PATENT CLAIMS An apparatus for adjusting the radial position of sinkers in a circular knitting machine, having a stitch length adjusting device, comprising a sinker carrier disposed in a plane perpendicular to the axis of the needle cylinder and carrying concentric locks, the inner lock being stationary and the outer lock consisting of radially movable sections; characterized in that the outer lock sections (7) are provided with protrusions (16) or depressions on the outer circumference and around the outer lock (7) a rotatable lock ring (17) provided with depressions (1) on the inner periphery is concentrically mounted on the support (1) 18) or protrusions opposing the peripheral protrusions (16) or the recesses of the outer lock (7) for radially displacing the sections of the outer lock (7) by rotating the lock ring (17). Device according to claim 1, characterized in that the peripheral projections (16) of the outer lock sections (7) have a rounded contour. Device according to claim 1 or 2, characterized in that the lock ring (17) is connected by a kinematic transmission (38) to the lifting and lowering mechanism (40) of the needle cylinder (39) and the sinker carrier (1). Device according to claim 3, characterized in that the locking ring (17) is connected by a pin (34) to a horizontal forked arm (32) connected via bevel gears (29, 30) and arms (22, 27) with a vertical bar (21) supported on the lift plate (19) for the needle cylinder (39).